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引用次数: 1
摘要
可逆电路的新兴技术为超低功耗量子计算系统的合成提供了一个潜在的解决方案。可逆电路可以设想为可逆门的级联,例如Toffoli门,它具有两个组件:k控制位和目标位(k- cnot), k大于或等于1。在分析可逆电路的可测试性问题时,经常使用缺门故障模型来模拟量子k-CNOT门的物理缺陷。在本文中,我们提出了一种新的可测试性设计(DFT)技术,用于使用弗雷德金门部署位交换的量子可逆电路。结果表明,在使用k-CNOT门实现的(n x n)电路中,仅添加两个额外输入以及几个弗雷德金门就可以在电路中易于测试。修改后的设计允许一个通用测试集(n + k + 2),该测试集可以检测原始电路中所有可检测的缺失门故障,其中k是所有k- cnot门中使用的最大控制数。与以前的方法相比,DFT在量子成本方面的开销也少得多。
Design-for-testability in reversible logic circuits based on bit-swapping
The emerging technology of reversible circuits offers a potential solution to the synthesis of ultra low-power quantum computing systems. A reversible circuit can be envisaged as a cascade of reversible gates only, such as Toffoli gate, which has two components: k control bits and a target bit (k-CNOT), k ⩾ 1. While analyzing testability issues in a reversible circuit, the missing-gate fault model is often used for modeling physical defects in quantum k-CNOT gates. In this paper, we propose a new design-for-testability (DFT) technique for quantum reversible circuits that deploys bit-swapping using Fredkin gates. It is shown that in an (n x n) circuit implemented with k-CNOT gates, addition of only two extra inputs along with a few Fredkin gates yields easy testability in the circuit. The modified design admits a universal test set of size (n + k + 2) that detects all detectable missing gate faults in the original circuit, where k is the maximum number of controls used among all k-CNOT gates. The DFT overhead in terms of quantum cost is also much less compared to previous approaches.
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